WO2005059645A9

WO2005059645A9 - Microlithography projection objective with crystal elements

Info

Publication number: WO2005059645A9
Application number: PCT/EP2004/014100
Authority: WO
Inventors: Karl-Heinz Schuster
Original assignee: Zeiss Carl Smt Ag; Karl-Heinz Schuster
Priority date: 2003-12-19
Filing date: 2004-12-10
Publication date: 2006-06-08
Also published as: WO2005059645A2; WO2005059645A3; WO2005059618A2; WO2005059618A3; JP5102492B2; US20070091451A1; US7755839B2; JP2007529762A

Abstract

A microlithography projection objective is proposed with optical elements, i.e. lenses or planar-parallel plates (used as end-closure plates) of crystalline magnesium fluoride, quartz, lanthanum fluoride, sapphire and Alpha-aluminium oxide. Suitable crystallographic orientations, crystal 10 combinations, and polarizations of the light are described. Suitable applications are for immersion lithography or near-field lithography in the DUV and VLN range, using the highest numerical aperture values.

Description

Microlithography Projection Objective with Crystal Elements

The invention relates to a microlithography projection objective with crystal elements, namely such made from materials showing birefringence and other than cubic crystal structure.

These are of relevance mainly as some of them show refractive indices well above those of quartz glass or calcium fluoride, what is a substantial need for immersion lithography with image side numerical apertures beyond 1.0 up to about 2 or more. From publications such as

Bruce W. Smith et al . Optical Microlithography XVII Proc. SPIE 5377 (2004), p 273 -284; Bruce W. Smith et al . Optical Microlithography XVI, Proc. SPIE 5040 (2003) , p 679 -689;

John H. Burnett et al . "High Index Materials for 193 run and 157 ran Immersion lithography" Int^Nl Symp. on Immersion & 157 run Lithography, Vancouver 8/2/04 (NIST/ Corning Tropel) and patent applications such as

WO2004/019 128 A2, or, commonly owned with this application:

US 6,717,722 B,

US Ser. No. 10/734,623 filed 15 Dec. 2003,

US Ser . No . 60/530,623 filed 19 Dec. 2003, us Ser . No . 60/530,978 filed 22 Dec. 2003, U uSs S Seerr.. N Noo.. 60/544,967 filed 13 Feb. 2004, us Ser . No . 60/568,006 filed 04 May 2004, us Ser . No . 60/592,208 filed 29 July 2004, us Ser . No . 60/591,775 filed 27 July 2004, us Ser . No . 60/612,823 filed 24 Sept 2004,

DE 10 2004 051 730.4 filed 22 Oct. 2004 some information about this art can be gathered.

Of these, e. g. WO 2004/019 128 A2, US 10/734,623, US 60/592,208, US 60/591,775 and US 60/612,823 show objective designs which can be optimized by and combined with the use of materials and teachings according to this application.

Suitable immersion liquids are inter alia described in US 60/568,006 or DE 10 2004 051 730.4. All cited documents are incorporated into this application by reference in their entirety. Their citation in no way constitutes any declaration on their relevance for this application, and the list certainly is incomplete and many more publications relate to this art.

D

For end-closure plates or for the last-positioned lens element in immersion objectives or near-field objectives there is a need for optical materials of the highest possible index of refraction. At the same time, the materials need to be transparent, homogeneous, radiation-resistant, as well as mechanically and chemically robust. There is a material which meets all of these conditions except for optical isotropy. The material is sapphire or, in chemical terms, Al₂O₃. Others are MgF₂ or LaF₃ and other uniaxial crystals.

In an absolutely telecentric light path and with completely tangential polarization it is possible to achieve complete isotropy of the light-transmitting properties by using the measures proposed by the present invention.

The claims together with this specification describe solutions to these problems and advantageous varieties.

Figures 1 to 8 and 10 to 13 are sketches that illustrate the principles of arrangements, or parts thereof, according to the invention.

Figure 9 shows wavelength-dependent variation of n_e and n_o for some materials from an article.

In the illustrated arrangements, for example in Figure 2, the sum (n_o-n_e)Al₂O₃ + (n_o-n_e)SiO₂ equals zero for a maximum-aperture ray B_max with an incident angle of 70° (n_o refractive index of ordinary ray, n_e refractive index of extraordinary ray) .

The following symbols are used in the drawings:

AS = aperture stop / system aperture

P = protector plate / protective element

I = immersion fluid, immersion

W = wafer, or the object to be exposed in the image plane OA = optical axis

L = lens

B_1113x = ray of maximum aperture

With tangential polarization of the light rays there is only one component, namely the p-component, and as a consequence, there is no phase shift between p- and s-components as long as the optical crystal axis of the crystal is oriented in exact parallel alignment with the optical axis of the objective. However, these conditions are met only approximately in practical cases. As a means to achieve perfect isotropy in the effect that a plate of this kind has on light rays, it is proposed according to the present invention that the plate be made of two parts. The proposed combination consists of an Al₂O₃ sapphire plate P₁ of optically negative character and an SiO₂ crystal plate P₂ of optically positive character, as illustrated in Figures 1 to 3. The magnitude of the birefringence changes individually with the wavelength. The plate thicknesses are therefore selected dependent on the wavelength, so that a birefringence of the Al₂O₃ plate is compensated by the complementary birefringence of the SiO₂ plate. This cannot be achieved completely, because the indices of refraction are different for the two materials, so that a compromise is necessary for different incident light angles. However, an exact compensation can be achieved in particular for the highest apertures which are relevant in immersion lithography applications, e.g., for dipole illumination.

In addition to a planar plate, the invention can also be used in a lens element. Since Al₂O₃ sapphire offers one of the highest known indices of refraction for the wavelengths of 157 run and 193 run, it is a preferred material to use for the element in the last position of the objective. Elements of crystalline SiO₂ are placed (in direction of light propagation) before the Al₂O₃ element.

Figure 4 represents a sketch to illustrate the principle, wherein the symbol QG stands for quartz glass, QK for quartz crystal, S for sapphire (which is at the same time a lens L in the sense of Figure 1) .

It also makes sense to use arrangements of elements that are joined together by wringing. The fact that the absolute amount of birefringence is larger in crystalline quartz is of practical significance because less of the SiO₂ crystal is needed for compensation. Also, crystalline SiO₂ has the smaller index of refraction and its use at the image-oriented end of a high-aperture immersion objective is therefore less advantageous.

An arrangement that is suitable for example for a wavelength of 193 nm is shown in Figure 5. The spaces between the lenses, particularly in the area near the image plane where there are large ray angles relative to the optical axis, can be filled by high-refractive fluids FLl of the same kind that are also used as an immersion medium. A double arrow in the lenses indicates the orientation of the optical axis of the birefringence that is inherent in the materials. It is clear that the effective index of refraction in the crystals Al₂O₃ and SiO₂ is subject to a continuous angle- dependent variation, but with tangentially polarized light there is initially no phase shift between an s-polarized and a p-polarized component. The variation of the refractive index is taken into account in the design.

Figure 6 illustrates an example of an objective for an operating wavelength of 157 ran with CaF₂ lenses of different crystallographic orientation, for example 111 and 110, for the compensation of intrinsic birefringence with a pair of optically uniaxial crystal lenses that is compensated in accordance with the invention. With immersion I or the near- field lithography technique, the objective can be coupled to the object to be exposed, for example a wafer W, with the largest possible numerical aperture.

Because of the high light-gathering power (etendue) , it is preferred to make the compensation. This is the best way to master the problem of extended fields outside of the telecentric light path without the split between s- polarization and p-polarization. Of course, with a skewed incident radiation in birefringent crystals, the n_e-components run outside the plane of incidence. However, with the different character of SiO₂ crystal and Al₂O₃ sapphire, it is possible to take specifically targeted countermeasures.

The term "negative optical character" means that the refractive index n_o of the ordinary ray is larger than the refractive index n_β of the extraordinary ray. The term "positive optical character" means that the refractive index n_o of the ordinary ray is smaller than the refractive index n_e of the extraordinary ray.

The scope of the invention includes: the compensation as described; the use of Al₂O₃ sapphire and SiO₂ crystal in lithography optics; the placement of the elements between the aperture stop or a conjugate location of the aperture stop and the image plane of a projection objective, with special preference for placing these elements in the bottom one-third of the distance between the aperture stop and the image plane; the use of the aforementioned materials for protector plates for immersion or near-field arrangements, either by themselves without compensation, or with compensation; the use at high angles of incidence >60°, with special preference >70°; including in these applications the compensation at the highest numerical aperture values NA (above 1.3 to 1.6) on the image side; also including the use of tangentially polarized light; and further including the use in immersion objectives with a refractive index of more than 1.8 in the last optical element, with special preference for more than 2.0; and also the use at an operating wavelength of 157 ran in conjunction with the crystals CaF₂, SiO₂, Al₂O₃ sapphire - in respectively different combined arrangements.

Similar to silicon dioxide, magnesium fluoride in crystalline form has an optically positive character. The advantage of MgF₂ lies in its high UV transmittance, particularly at 157 nm. Its drawback is the low coefficient of refraction, for example at a wavelength of 193.304 nm, with values of n_o = 1.427460 and n_e = 1.441069.

The compensation of birefringence in a high-aperture end- closure part of a microlithographic projection objective requires the availability of suitable degrees of freedom. If the birefringence were of exactly equal magnitude and had the same form in Al₂O₃ as in quartz crystal, an exact solution that provides compensation for all angles would exist at least for planar-parallel plates, i.e., one would only need to use two plates of equal thickness. If lenses are used instead of plates, the possible phase differences occurring as a result of refraction and birefringence become larger and there is an increased risk that this will affect the image quality. On the other hand, with lenses one has the possibility to use a targeted variation of the radii as a further degree of freedom in addition to the thickness, as a parameter for compensation.

Based on these considerations, a further material is proposed for an additional fine correction, namely MgF₂ crystal. In view of its low index of refraction, it is placed preferably in a position before the more strongly refractive elements of quartz crystal and sapphire. It should be noted in this context that the uniaxial birefringent crystals Al₂O₃ sapphire, SiO₂, MgF₂ are compensated in an entirely different manner than the CaF₂, SrF₂, and BaF₂ crystals and the like which are a priori isotropic (at least in the visible range) .

The refractive index of the successive elements, for example at the 157 run wavelength in the example of Figure 7, is continuously increased towards the wafer (image plane) , namely up to a level of more than 2.0.

The optical path lengths for s-and p-polarization are largely equalized for the broadest possible range of angles through the simultaneous use of three crystalline materials Al₂O₃, SiO₂, and MgF₂. It should be noted that the harmful contributions for skewed rays increase the farther one moves these elements away from the wafer, i.e., from the image plane. This also provides the special possibility of a compensation based on where a lens of each of the respective materials is positioned. The optical path length should to the greatest extent possible meet the condition (n_o-njAl₂O₃-d, + (n_o-n_e) SiO₂ ^•d₂ + (n_o-n_e)MgF₂ ^•d₃ = 0, wherein n_o represents the refractive index for the ordinary ray, n_e represents the refractive index for the extraordinary ray, and d₁ d₂, d₃ represent the respective path lengths inside the crystals. It should be the aim (and it is possible) to meet the condition particularly well in the aperture angle range from 65° to 72°.

The scope of the invention likewise includes a lithography objective in a projection system, where the effect of birefringence of uniaxial crystal materials in end-closure plates or lenses on the image side of the objective is completely corrected for angles in the range from 65° to 72° (measured geometrically from the optical axis) .

Instead of using Al₂O₃ sapphire for the compensation or as a provider for the primary refractive power in this end range, one could also use the uniaxial crystal material LaF₃ as a further possible lens material. Like Al₂O₃, it has a negative optical character and the birefringence values likewise resemble those of Al₂O₃. In comparison to sapphire, LaF₃ has the advantage that the commercially available crystals, which are made in a completely different manufacturing process, currently meet higher standards of optical quality. LaF₃ is water-insoluble, but it does not come up to the levels of hardness and UV transmittance of Al₂O₃ sapphire.

Figure 8 schematically illustrates an example for an operating wavelength of 193 nm where LaF₃ is used for the last lens on the image side, in this case with a protector plate P of α-Al.O_j. In this case, too, the alternative to an arrangement with an immersion fluid is an optical near field where the distance between the protector plate P and the wafer is shorter than the operating wavelength.

With this plate P of Al₂O₃ it is very important to pay attention to the fact that the α-modification of the crystal represents the advantageous choice. The γ-modification of Al₂O₃ is hygroscopic and should not be used.

Table 1 :

Refractive indices of the uniaxial crystals

MgF₂ wavelength ordinary extraordinary

248.338 nm 1.403248 1.416080

193.304 nm 1.427460 1.441069

157.629 nm 1.466666 1.481281

SiO₂ wavelength ordinary extraordinary

248.338 nm 1.601568 1.612689

193.304 nm 1.660455 1.673963

Difference between indices Δn = n_o - n_e 157.629 nm Al₂O₃ 0.012973

MgF₂ 0.014243

The birefringence values were measured by the interference method and are more reliable than measuring the indices n_o and n_e by means of prisms and taking the differences. In regard to this topic, reference is also made to an article in Applied Optics, March 1969, Volume 8 No. 3, p. 673, where the wavelength-dependent variation of n_e and n_o is discussed.

Figure 9 is copied from Fig. 3 of the aforementioned reference.

Further according to the invention, uniaxial crystals are compensated as follows:

Lenses LPP of positive refractive power and positive optical character are compensated by lenses LPN of positive refractive power with negative character (Fig. 10) . In addition, lenses of positive refractive power can also be compensated with lenses of negative refractive power with the same character, as shown in the example of Figure 11 - with positive character in the lenses LPP, LNP (negative refractive power) , possibly supplemented by a lens LPN. Figure 12 shows an arrangement where lenses LPN, LNN, LPP follow each other, with LNN being a lens of negative refractive power and negative optical character.

As a further example, Figure 13 shows the four last lenses on the image side of a microlithography projection objective with the materials according to the invention as the significant mass (material) of the lenses, which may be coated with layers for antireflection, anticorrosion or the like (as in the other embodiments discussed), i.e., MgF₂ /

SiO₂ crystal / optional fluid lens / LaF₃ / Al₂O₃ sapphire, and with appropriate compensation of imaging errors due to birefringence effects of the lens materials.

Claims

Patent Claims:

1. Microlithography projection objective with at least one lens of quartz crystal and with at least one lens of sapphire crystal.

2. Microlithography projection objective with at least two transmittent optical elements, in particular lenses (L) or planar-parallel plates (P) consisting of crystals that are uniaxial with regard to birefringence, wherein at least two of said optical elements consist of different crystal materials.^'

3. Microlithography projection objective according to claim 1 or claim 2, characterized in that an axis of birefringence of a first optical element and an axis of birefringence of a second optical element each run parallel to the optical axis of the geometrical light ray path inside the projection objective.

4. Microlithography projection objective according to at least one of the preceding claims, characterized in that said lenses (L) or optical elements (P) are arranged on the image side of a pupil or system aperture (AS) that is nearest to the image plane.

5. Microlithography projection objective according to at least one of the preceding claims, characterized in that said lenses (L) or optical elements (P) are among the three optical elements that lie closest to the image plane (W) .

6. Microlithography projection objective according to at least one of the preceding claims, characterized in that the numerical aperture on the image side is larger than 1.6 and with special preference larger than 1.8.

7. Microlithography projection system with a microlithography projection objective according to at least one of the claims 1 to 6.

8. Microlithography projection system according to claim 7, characterized in that polarized light passes through said crystalline lenses or crystalline optical elements.

9. Microlithography projection system according to claim 8, characterized in that the light is tangentially polarized.

10. Microlithography projection system according to claim 8, characterized in that the light is linearly polarized.

11. End-closure plate of a microlithography projection objective substantially made of α-Al₂O₃.

12. Use of an LaF₃ lens or LaF₃ planar-parallel plate in a microlithography projection objective.

13. Microlithography projection objective with at least two optical elements from the group that comprises lenses and planar-parallel plates substantially consisting of a material from the group that comprises crystals of MgF₂, SiO₂, LaF₃, sapphire, Ot-Al₂O₃.

14. Microlithography projection objective according to claim 13, characterized by the presence of two or three different materials selected from said group of crystals.